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Types of Errors in Numerical Methods

What are numerical methods?

Many engineering problems are too time consuming to solve or may not be able to be solved analytically. In these situations, numerical methods are usually employed. Numerical methods are techniques designed to solve a problem using numerical approximations. An example of an application of numerical methods is trying to determine the velocity of a falling object. If you know the exact function that determines the position of your object, then you could potentially differentiate the function to obtain an expression for the velocity. More often, you will use a machine to record readings of times and positions that you can then use to numerically solve for velocity:

where f is your function, t is the time of the reading, and h is the distance to the next time step.

Because your answer is an approximation of the analytical solution, there is an inherent error between the approximated answer and the exact solution. Errors can result prior to computation in the form of measurement errors or assumptions in modeling. The focus of this blog post will be on understanding two types of errors that can occur during computation: roundoff errors and truncation errors.

Roundoff Error

Roundoff errors occur because computers have a limited ability to represent numbers. For example, π has infinite digits, but due to precision limitations, only 16 digits may be stored in MATLAB. While this roundoff error may seem insignificant, if your process involves multiple iterations that are dependent on one another, these small errors may accumulate over time and result in a significant deviation from the expected value. Furthermore, if a manipulation involves adding a large and small number, the effect of the smaller number may be lost if rounding is utilized. Thus, it is advised to sum numbers of similar magnitudes first so that smaller numbers are not “lost” in the calculation.

One interesting example that we covered in my Engineering Computation class, that can be used to illustrate this point, involves the quadratic formula. The quadratic formula is represented as follows:

Using a = 0.2, b = – 47.91, c = 6 and if we carry out rounding to two decimal places at every intermediate step:

The error between our approximations and true values can be found as follows:

As can be seen, the smaller root has a larger error associated with it because deviations will be more apparent with smaller numbers than larger numbers.

If you have the insight to see that your computation will involve operations with numbers of differing magnitudes, the equations can sometimes be cleverly manipulated to reduce roundoff error. In our example, if the quadratic formula equation is rationalized, the resulting absolute error is much smaller because fewer operations are required and numbers of similar magnitudes are being multiplied and added together:

Truncation Error

Truncation errors are introduced when exact mathematical formulas are represented by approximations. An effective way to understand truncation error is through a Taylor Series approximation. Let’s say that we want to approximate some function, f(x) at the point xi+1, which is some distance, h, away from the basepoint xi, whose true value is shown in black in Figure 1. The Taylor series approximation starts with a single zero order term and as additional terms are added to the series, the approximation begins to approach the true value. However, an infinite number of terms would be needed to reach this true value.

where Rn is a remainder term used to account for all of the terms that were not included in the series and is therefore a representation of the truncation error. The remainder term is generally expressed as Rn=O(hn+1) which shows that truncation error is proportional to the step size, h, raised to the n+1 where n is the number of terms included in the expansion. It is clear that as the step size decreases, so does the truncation error.

The Tradeoff in Errors

The total error of an approximation is the summation of roundoff error and truncation error. As seen from the previous sections, truncation error decreases as step size decreases. However, when step size decreases, this usually results in the necessity for more precise computations which consequently results in an increase in roundoff error. Therefore, the errors are in direct conflict with one another: as we decrease one, the other increases.

However, the optimal step size to minimize error can be determined. Using an iterative method of trying different step sizes and recording the error between the approximation and the true value, the following graph shown in Figure 2 will result. The minimum of the curve corresponds to the minimum error achievable and corresponds to the optimal step size. Any error to the right of this point (larger step sizes) is primarily due to truncation error and the increase in error to the left of this point corresponds to where roundoff error begins to dominate. While this graph is specific to a certain function and type of approximation, the general rule and shape will still hold for other cases.

Figure 2: Plot of Error vs. Step Size (Chapra, 2017)

Hopefully this blog post was helpful to increase awareness of the types of errors that you may come across when using numerical methods! Internalize these golden rules to help avoid loss of significance:

Avoid subtracting two nearly equal numbers

If your equation has large and small numbers, work with smaller numbers first

Consider rearranging your equation so that numbers of a similar magnitude are being used in an operation

3 thoughts on “Types of Errors in Numerical Methods”

This is an interesting article. I had some trouble following the terms in the “rationalized” version of the quadratic equation. Was there a reason that ‘a’ was repaced by ‘c’? Does this approach evaluate (1/x) rather than x, using the quadratic equation with numerator and denominator terms inverted?

Rationalizing the quadratic equation involves multiplying the numerator and denominator by the conjugate of the equation and this approach still solves for x, not 1/x. Please see this website for the step-by-step derivation of the equation.